Front filter in plasma display panel

ABSTRACT

Disclosed is a front filter in a plasma display panel (PDP), in which the front filter comprises an impact-absorbing layer attached to a front surface of the panel and composed of one of EVA, acrylic polymers, and PVC to be able to absorb external impacts.

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention relates in general to front filters in a plasmadisplay panel, more particularly, to a front panel for improvingdurability of a plasma display panel.

2. Discussion of the Background Art

Principle of plasma display panel displays (hereinafter referred to asPDP) technology is that 147 nm-ultraviolet rays generated by dischargeof different compositions of inert gas mixtures, such as, He+Xe, Ne+Xeor He+Ne+Xe, irradiate phosphors emitting in either red, green, or blueto display images including characters or graphics. The PDP technologyis at mass production stage, and recent advances in PDP technologiesmade easier to manufacture thin PDPs and to provide much improvedpicture quality. Especially, in case of a three-electrode surfacedischarge type PDP, charge particles formed by discharge (i.e. wallcharge) are stacked on the surface, which in turn protect electrodesfrom sputtering originated by discharge. Thus, the three-electrodesurface discharge type PDP is known for low consumption of voltage andlong lifespan.

FIG. 1 is a perspective view of the structure of a discharge cell in arelated art PDP.

Referring to FIG. 1, the discharge cell of the related art PDP adoptingtie three-electrode surface discharge type structure includes a scanelectrode (Y) and a sustain electrode (Z) formed on an upper substrate10, and an address electrode (X) formed on a lower substrate 18. Thescan electrode (Y) and the sustain electrode (Z) respectively includestransparent electrodes (12Y and 12Z), and metal bus electrodes (13Y and13Z) formed on an edge of the transparent electrodes (12Y and 12Z) andhaving a smaller line width than that of the transparent electrodes (12Yand 12Z).

In general, the transparent electrodes (12Y and 12Z) are composed ofIndium-Tin-Oxide (ITO) and formed on the upper substrate 10. The metalbus electrodes (13Y and 13Z) are typically made of chrome (Cr) andformed on the transparent electrodes (12Y and 12Z), reducing voltagedrop caused by the highly resistive transparent electrodes (12Y and127Z). Also, an upper dielectric layer 14 and a protective film 16 arelayered on the upper substrate 10 on which the scan electrode (Y) andthe sustain electrode (Z) ate formed side by side. The charge particlesformed by discharge (i.e. wall charge) are stacked on this upperdielectric layer 14. The protective film 16 protects the upperdielectric layer 14 from damages caused by sputtering during plasmadischarge, and increases ejection rate of secondary electrons. Usuallymagnesium oxide (MgO) is used for the protective film 16.

On the lower substrate 18 on which the address electrode X is formed isa lower dielectric layer 22 and a barrier rib 24. Surfaces of die lowerdielectric layer 22 and the barrier rib 24 are coated with a phosphorlayer 26. The address electrode (X) is formed at right angles to thescan electrode (Y) and the sustain electrode (Z). The barrier rib 24 isformed in a strip or lattice pattern, and prevents ultraviolet rays andvisible rays generated by discharge from leaking by an adjacentdischarge cell. The phosphor layer 26 is excited by ultraviolet raysgenerated by plasma discharge, and generates one of visible rays in red,blue, or blue. The mixed inert gas is injected to discharge space formedin between the upper/lower substrate 10, 18 and the battier rib 24.

To obtain continuous-tone images, each frame of PDP is divided into aplurality of subfields with different frequencies of the radiation intime-sharing system. Each subfield is composed of three parts: a resetperiod for resetting the full screen, an address period for selecting ascan line and for selecting a cell among the selected scan line, and asustain period for display images in gray scales according to thefrequency of discharge.

For instance, suppose that an images needs to be displayed in 256 grayscales. Then, as shown in FIG. 2, a frame period (16.67 ms)corresponding to 1/60 sec is divided into 8 subfields (SF1 through SF8).As described above, each of these eight subfields (SF1 through SF8) iscomposed of three parts, namely the reset period, the address period,and the sustain period. The reset and address periods of each subfieldare same for each subfield, but the sustain period of each subfield isexponentially increased at the rate of 2^(n) (n=0,1,2,3,4,5,6,7).

Moreover, a front filter is installed at the upper substrate 10 of thePDP, to shield electromagnetic wave and to prevent reflection ofexternal light.

FIG. 3 is a cross-sectional view of one side of a related art PDP.

Referring to FIG. 3, the related art PDP includes a panel 32 for whichan upper substrate and a lower substrate are tightly adhered to eachother, a front filter 30 installed at the front surface of the panel 32,a heat radiation plate 34 installed at the rear surface of the panel 32,a printed circuit substrate 36 attached to the heat radiation plate 34,a back cover 38 for compassing the rear surface of the PDP, a filtersupporting part 40 for connecting the front filter 30 to the back cover38, and a bearing member 42 installed in between the front filter 30 andthe back cover 38 to compass the filter supporting part 40.

The printed circuit substrate 36 sends actuation signals to theelectrodes of the panel 32. To this end, the printed circuit substrate36 is mounted with diverse driving parts that are not shown in FIG. 3.The panel 32, in response to the actuation signal provided from theprinted circuit substrate 36, displays a desired image. The heatradiation plate 34 radiates heat generated from the panel 32 and theprinted circuit substrate 36. The back cover 38 protects the panel 32from external impacts, and blocks ElectroMagnetic Interference(hereinafter referred to as EMI) in the rear surface.

The filter supporting part 40 electrically connects the front filter 30to the back cover 38. In other words, the filter supporting part 40earths the front filter 30 to the back cover 38, and prevents anoccurrence of EMI on the side. The bearing member 42 bears the filtersupporting part 40, the front filter 30, and the back cover 38.

The front filter 30 not only shields EMI but also prevents thereflection of external light. To this end, as shown in FIG. 5, the frontfilter 30 includes an antireflection coating 50, an opticalcharacteristic film 52, a glass 54, an EMI shielding film 56, and a nearinfrared rays (hereinafter referred to as NIR) blocking film 58. Inreality, an adhesive intermediate film is formed in between adjacentfilms (50, 52, 54, 56, and 58) of the front filter 30.

In addition, the optical characteristic film 52 is not usually anindependent separate layer as shown in the drawing. Instead, the opticalcharacteristic film 52 is formed by infusing a specific material to theadhesive intermediate film.

The structure of the front filter 30 is slightly different, depending onwhich manufacturer produces the front filter. For the convenience ofdescription of the invention, the adhesive intermediate film is notillustrated in the drawings. However, the optical characteristic film 52is well illustrated as a separate layer, and the structure of the frontfilter 30 is the one currently being used in the PDP.

The antireflection coating 50 prevents the reflection of an incidentlight from outside and thus, improves contrast of images on the PDP. Theantireflection coating 50 is formed on the surface of the front filter30. In some cases, the antireflection coating 50 can be formedadditionally on the rear surface of the front filter 30 as well. Theoptical characteristic film 52 reduces the brightness of red (R) andgreen (G) rays among incident light from the panel 32 but increases thebrightness of blue (B) ray, thereby improving optical characteristics ofthe PDP.

The glass 54 protects the front filter 30 from external impacts. Inother words, the glass 54 supports the front filter 30 in order toprevent the front filter 30 and the filter 32 from being damaged byexternal impacts. The EMI shielding film 56 shields EMI, and preventsthe ejection of EMI incidented from the panel 32 to the outside. The NIRblocking film 58 blocks NIR radiation from the panel 32, and using an IRlike a remote controller, helps signal-transmitting devices to able todo their work as normally by preventing an excess of the ejection of NIRto the outside more than what is required. In the meantime, the EMIshielding film 56 and the NIR blocking film 58 can be integratedtogether, instead of being separate layers.

The above described front filter 30 is then electrically connected tothe back cover 38 through the filter supporting part 40. To be morespecific, the filter supporting part 40 is connected to the bothcomponents in such manner that it covers from one end of the frontfilter 30 to the rear surface of the front filter 30. Here, the filtersupporting part 40 is electrically connected to at least one of the EMIshielding film 56 and die NIR blocking film 58. That is, by earthing thefront filter 30 to the back cover 38, the filter supporting part 40 canshield the EMI and/or NIR effects.

Therefore, the glass 54 in the related art front filter 30 serves toprotect the front filter 30 from external impacts. However, one ofdisadvantages of using the glass 54 is that the thickness of the frontfilter 30 with the glass 54 is increased. In addition, when the glass 54is inserted to the front filter 30, total weight and cost of manufactureare increased.

To resolve the above problems, a film type front filter 60 without theglass 54 is newly introduced, as depicted in FIG. 6. The film type frontfilter 60 includes an antireflection coating 62, an opticalcharacteristic film 64, an EMI shielding film 66, and an NIR blockingfilm 68. An adhesive intermediate layer is formed in between adjacentfilms 62, 64, 66, and 68 of the film type front filter 60 to adhere thefilms to one another. In general, the optical characteristic film 60 isnot a separate layer, but formed by infusing a specific material to theadhesive intermediate layer. The structure of the front filter 60 isslightly different, depending on which manufacturer produces the frontfilter 60. For the convenience of description of the invention, theadhesive intermediate film is not illustrated in the drawings. However,the optical characteristic film 64 is shown as a separate layer.

The antireflection coating 62 is formed on the surface of the film typefront filter 60, and prevents the reflection of an external incidentlight back to the outside. The optical characteristic film 64 dims downred (R) and green (G) rays among incident light from the panel 32 butincreases the brightness of blue (B) ray, thereby improving opticalcharacteristics of the POP.

The EMI shielding film 66 shields EMI, and prevents the ejection of EMIincidented from the panel 32 to the outside. The EMI shielding film 66can be integrated with the NIR blocking film 68 which will be discussednext.

The NIR blocking film 66 blocks the incidence of NIR from the panel 32.Here, NIR has a wavelength of 700-1200 nm, and is generated by Xe thatemits 800-1000 nm rays during the discharge of mixed inert gases filledin the PDP panel. When the NIR is ejected to the outside,signal-transmitting devices like a remote controller for transmittingsignals via IR do not work. As a result, signals cannot be transmittedto the PDP any more. That is to say, the ejection of the NIR causesmalfunction of the remote controller Hence, the NIR blocking film 68made of NIR absorbing materials (or colorant) prevents an excess of theejection of NIR to the outside more than what is required, to ensurethat signals from the remote controller for example are properlytransmitted to die panel 32.

The merits of the film type front filter 60 are that the film type frontfilter without the glass 54 is lighter and thinner than the front filterwith the glass 54. Also, the film type front filter 60 can reduce costof manufacture by not using the glass 54.

However, the film type front filter 60 without the glass 54, i.e. atempered glass, is very susceptive to damages from external impacts, andthis results in a much higher possibility to cause serious damages onthe screen than to the front filter with the glass 54.

SUMMARY OF THE INVENTION

An object of the invention is to solve at least the above problemsand/or disadvantages and to provide at least the advantages describedhereinafter.

Accordingly, one object of die present invention is to solve theforegoing problems by providing a film type front filter for reinforcingdurability of a plasma display panel.

The foregoing and other objects and advantages are realized by providinga front filter including a front filter including: a panel; and animpact-absorbing layer attached to a front surface of tie panel andabsorbing external impacts.

In an embodiment of the invention, the front filter further comprises anantireflection coating for reducing reflection of light, an opticalcharacteristic layer for improving optical characteristics of incidentrays from the panel, an EMI (electromagnetic interference) shieldingfilm for shielding incident electromagnetic waves incidented from thepanel; and an NIR (near infrared rays) blocking film for blockingincident near rays from the panel.

In an embodiment of the invention, the impact-absorbing layer is made ofa film, and being attached in between the films.

In an embodiment of the invention, the impact-absorbing layer isfabricated in form of an adhesive or a cohesion agent, and infused inbetween the films.

In an embodiment of the invention, the impact-absorbing layer iscomposed of one of polymer materials out of transparent material EVA,acrylic polymers and PVC.

In an embodiment of the invention, the impact-absorbing layer has athickness of 500 μm-5 mm.

Another aspect of the invention provides a front filter in a plasmadisplay panel, wherein the front filter comprises an impact-absorbinglayer attached to a front surface of the panel and composed of one ofEVA, acrylic polymers, and PVC to be able to absorb external impacts.

In an embodiment of the invention, the impact-absorbing layer has athickness of 500 μm-5 mm.

In an embodiment of the invention, the impact-absorbing layer is a filmtype.

In an embodiment of the invention, the impact-absorbing layer is appliedin form of -an adhesive or a cohesion agent.

In an embodiment of the invention, the front filter further comprises anantireflection coating for reducing reflection of light, an opticalcharacteristic layer for improving optical characteristics of incidentrays from the panel, an EMI (electromagnetic interference) shieldingfilm for shielding incident electromagnetic waves incidented from thepanel; and an NIR (near infrared rays) blocking film for blockingincident near rays from the panel.

Additional advantages, objects, and features of the invention will beset forth in part in die description which follows and in part willbecome apparent to those having ordinary skill in the art uponexamination of the following or may be learned from practice of theinvention. The objects and advantages of the invention may be realizedand attained as particularly pointed out in the appended claims.

BRIEF DESCRIPTION OF THE DRAWINGS

The invention will be described in detail with reference to thefollowing drawings in which like reference numerals refer to likeelements wherein:

FIG. 1 is a perspective view of the structure of a discharge cell in arelated art PDP;

FIG. 2 illustrates a frame in 256 gray scales for used in a related artplasma display panel;

FIG. 3 is a cross-sectional view of one side of a related art PDP;

FIG. 4 is a cross-sectional view of the front filter in FIG. 3;

FIG. 5 is a detailed exploded view illustrating an earthing process onthe front filter in FIG. 3 and a filter supporting part;

FIG. 6 is a cross-sectional view of a related art film type frontfilter; and

FIG. 7 is a cross-sectional view of a front filter according to thepresent invention.

DETAILED DESCRIPTION OF PREFERRED EMBODIMENTS

The following detailed description ill present a film type front filterfor a plasma display panel according to a preferred embodiment of theinvention in reference to the accompanying drawings.

FIG. 7 is a cross-sectional view of the front filter in a plasma displaypanel (PDP) according to the present invention.

Referring to FIG. 7, the film type front filter 80 includes anantireflection coating 82, an optical characteristic film 86, an EMIshielding film 88, an NIR blocking film 90, and an impact-absorbinglayer 84. An adhesive intermediate layer is formed in between adjacentfilms 82, 84, 86, 88, and 90 of the film type front filter 80 and inbetween the panel 32 and the films, thereby adhering them together. Ingeneral, the optical characteristic film 86 is not a separate layer, butformed by infusing a specific material to the adhesive intermediatelayer. The structure of the front filter 80 is slightly different,depending on which manufacturer produces the front filter 60. For theconvenience of description of the invention, the adhesive intermediatefilm is not illustrated in the drawings. However, the opticalcharacteristic film 86 and the NIR blocking film 90 are shown asseparate layers.

The antireflection coating 82 is formed on tie surface of the film typefront filter 80, and prevents the reflection of an external incidentlight back to the outside. The antireflection coating 82 can be formedadditionally on the rear surface of the film type front filter 80.

The optical characteristic film 86 dims down red (R) and green (&) raysamong incident light from the panel 32 but increases the brightness ofblue (B) ray, thereby improving optical characteristics of the PDP.

The EMI shielding film 88 shields EMI, and prevents the ejection of EMIincidented from the panel 32 to the outside. The EMI shielding film 88can be integrated with the NIR blocking film 90 which will be discussednext.

The NIR blocking film 90 blocks the incidence of NIR from the panel 32.Here, NIR has a wavelength of 700-1200 nm, and is generated by Xe thatemits 800-1000 nm rays during the discharge of mixed inert gases filledin the PDP panel. When the NIR is ejected to the outside,signal-transmitting devices like a remote controller for transmittingsignals via IR do not work. As a result, signals cannot be transmittedto the PDP any more. That is to say, the ejection of the NIR causesmalfunction of the remote controller. Hence, the NIR blocking film 90made of NIR absorbing materials (or colorant) prevents an excess of theejection of NIR to the outside more than what is required, to ensurethat signals from the remote controller for example are properlytransmitted to the panel 32.

The impact-absorbing layer 84 is a separate film, and either it isattached to other films 82, 86, 88, and 90, or it can be manufactured inform of an adhesive or a cohesion agent to be infused in betweenadjacent films 82, 86, 88, and 90. The impact-absorbing layer 84 can bemade of various polymer materials, e.g., transparent material EVA,acrylic polymers, or PVC, and has a thickness of 500 μm-5 mm.

Basically, the impact-absorbing layer of the film type front filterimproves a breaking strength of the screen display by absorbing externalimpacts.

In other words, the impact-absorbing layer plays a role as a temperedglass used in the related art front filter with a glass. It preventsdeterioration of breaking strength of the screen display, which in factis one of defects of the related art film type front filter, and thusimproves durability of the film type front filter.

As discussed above, the film type front filter with tie impact-absorbinglayer of the present invention can reduce possible damages on thedisplay caused by external impacts, and improve breaking strength of thepanel.

As a result, the impact-absorbing layer adapted to the film type frontfilter according to the invention plays a role as the tempered glassused in the related art front filter with the glass. In this manner, itis possible to obviate problems like deteriorations in breaking strengthof die screen display, which is known as one of defects of die relatedart film type front filter, and to improve durability of the film typefront filter.

While the invention has been shown and described with reference tocertain preferred embodiments thereof, it will be understood by thoseskilled in the art that various changes in form and details may be madetherein without departing from the spirit and scope of the invention asdefined by the appended claims.

The foregoing embodiments and advantages ate merely exemplary and arenot to be construed as limiting the present invention. The presentteaching can be readily applied to other types of apparatuses. Thedescription of the present invention is intended to be illustrative, andnot to limit the scope of the claims. Many alternatives, modifications,and variations will be apparent to those skilled in the art. In theclaims, means-plus-function clauses are intended to cover the structuresdescribed herein as performing the recited function and not onlystructural equivalents but also equivalent structures.

1. A plasma display panel comprising. a panel; a front filter formed onthe front surface of the panel; a printed circuit substrate for sendingactuation signals to the panel; and a back cover for encompassing therear surface of the panel, wherein the front filter includes a nearinfrared blocking film formed directly on the front surface of the panelfor blocking near infrared light rays emerging from the panel, anelectromagnetic interference shielding film formed on the near infraredblocking film for blocking electromagnetic interference rays emergingfrom the panel, an optical characteristic film formed on dieelectromagnetic interference shielding film for selectively filteringlight rays emitted from the panel wherein the optical characteristicfilm decreases the intensity of red and green rays among incident lightfrom the panel, and increases the intensity of blue ray emitted from thepanel, an impact-absorbing layer formed on the optical characteristicfilm for improving optical characteristics of incident rays from thepanel, and an antireflection coating formed on the impact-absorbinglayer to prevent incident light rays being reflected from the panel. 2.The plasma display panel according to claim 1, wherein theimpact-absorbing layer is fabricated an adhesive or a cohesion agent,and infused between the optical characteristic film and theantireflection coating.
 3. The plasma display panel according to claim1, wherein the impact-absorbing layer is film type.
 4. The plasmadisplay panel according to claim 1, wherein the impact-absorbing layerhas a thickness selected from the range of approximately 500 μm toapproximately 5000 μm.
 5. The plasma display panel according to claim 1,wherein the panel is a plasma display panel, and wherein theimpact-absorbing layer is composed of transparent polymer materialselected from the group consisting of: an EVA, an acrylic polymer, and aPVC.
 6. The plasma display panel according to claim 5, wherein theimpact-absorbing layer has a thickness selected from the range ofapproximately 500 μm to approximately 5000 μm.
 7. The plasma displaypanel according to claim 5, wherein the impact-absorbing layer isinfused between the optical characteristic film and the antireflectioncoating.
 8. The plasma display panel according to claim 5, wherein theimpact-absorbing layer is applied to the optical characteristic film inform of an adhesive or a cohesion agent.
 9. A plasma display panel for adisplay panel, comprising: a panel; a front filter formed on the frontsurface of the panel; a printed circuit substrate for sending actuationsignals to the panel; and a back cover for encompassing the rear surfaceof the panel, wherein the front filter includes a near infrared blockingfilm formed directly on the panel for blocking excess near infraredlight rays emerging from the panel, an electromagnetic interferenceshielding film formed on the near infrared blocking film for blockingfilm light rays emerging from the panel to outside the panel, an opticalcharacteristic film formed on the electromagnetic interference shieldingfilm wherein the optical characteristic film dims the level of red andgreen light rays emitted by the panel and to increase the level ofbrightness of blue light emitted by the panel, and an impact-absorbinglayer formed on the optical characteristic film, wherein theimpact-absorbing layer selected from the group of transparent polymermaterials consisting of: an EVA and an acrylic polymer and a PVC and anantireflection coating formed on the impact-absorbing layer to preventreflection of external light arriving from the panel.
 10. A plasmadisplay panel comprising: a panel; a front filter formed on the frontsurface of the panel; a printed circuit substrate for sending actuationsignals to the panel; and a back cover for encompassing the rear surfaceof the panel, wherein the front filter includes a near infrared blockingfilm disposed directly on die panel for blocking excess near infraredlight rays emerging from the panel, a first impact-absorbing layerformed on the near infrared blocking film, an electromagneticinterference shielding film formed on the first impact-absorbing layerfor blocking film light rays emerging from the panel to outside thepanel, a second impact-absorbing layer formed on die electromagneticinterference shielding film, a optical characteristic film formed on thesecond impact-absorbing layer for selectively filtering light raysemitted from the panel, a third impact-absorbing layer is formed on theoptical characteristic film, and an antireflection coating disposed onthe third impact-absorbing layer to prevent reflection of external lightarriving from the panel.
 11. The plasma display panel according to claim10, wherein the optical characteristic film decreases the intensity ofred and green rays among incident light from the display panel, andincreases the intensity of blue ray emitted from the panel.